Teleticket system



June 9 E. HOPKINS TELETICKET SYSTEM Filed Oct. 26. 1929 8 Sheets-Sheet l June 11, 1935. E opKlNs TELETICKET SYSTEM 8 Sheets-Sheet 2 Filed Oct. 26, 1929 R. 0 T N E N E. HOPKINS 2,004,112

TELETICKET SYSTEM Filed Oct. 2", 1929 8 Sheets-Sheet 3 June 11, 1935.

June 1 1, 1935. E HOPKINS 2,004,112

TELETICKET SYSTEM I Filed 001;. 26, 1929 8 Sheets-Sheet 4 $56 3 73 qoo 449 INVENTOR:

June 11, 1935. HOPKINS TELETICKET SYSTEM File'd Oct. 25, 1929 8 Sheets-Sheet 5 8 Sheets-Sheet 6 June 11, 1935. E. HOPKINS TELETICKE T SYSTEM Filed Oct. 25, 1929 an 8 6 I 2:

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June 11, 1935. E. HOPKINS 2,004,112

' TELETICKET SYSTEM Filed Oct. 26, 1929 8 Sheets-Sheet 8 uze L M L Ll K 2 5- INVENTOR':

Patented June 11 1935 UNITED STATES PATENT OFFICE TELETICKET SYSTEM Edwin Hopkins, New York, N. Y.

Application October 26, 1929, Serial N 0. 402,714

25 Claims.

The main purpose of my invention is to provide means for printing theatre tickets by telegraph at-a number-of stations located at various distances from the theatre. Thus stations in drug stores and elsewhere throughout a city may print tickets for any theatre in the system, the printing being under the control of the theatre to which tickets are desired.

In a system of eighty theatres fitted with sending apparatus and a thousand stores in which are located printing apparatus, any such station may telephone any theatre and when it is ascertained that the theatre has tickets acceptable to the purchaser visiting the station, the theatre sets the printing apparatus by telegraphic signals over the telephone wires and the station operator then operates the printer, the theatre operator automatically cancelling his ticket at the same time. The theatre operators sending apparatus permits him to send signals which will only print tickets for his theatre. But he may have a printer and thus be able to secure tickets for any other theatre if desired by his patron.

It is also within my invention to'keep a group of sending machines and supplies of tickets for all theatres at a central ofiice, and outlying stations may obtain their tickets through the central station. In such case the sending apparatus is fitted with means for selling tickets for all theatres. One sender may be fitted for a small group of theatres and if a distant patron does not wish seats available for any of those, the call may be switched to another small group without compelling the patron to telephone to a number of different theatres from the printing station.

The apparatus consists chiefly of a sending apparatus adapted to be set by its keys to send a series of electrical impulses in groups 'of alternating impulses, prolongations of one such impulse and dead spaces, from a series of sending discs coming into action automatically in succession, and a receiving-printing apparatus With a multiple number of type wheels adapted to be set to the printing position by the several groups of impulses, automatically in succession. When the type wheels are thus set the printer station operator prints the ticket by manual operation. The printer then clears itself auomatically, but the sending operator by changing a single key may send the adjoining seat without resetting his apparatus, which he clears by manual operation when through, automatically cancelling the tickets sent.

Further features of the invention willbe found set forth in detail hereinafter.

In carrying out my invention I find it generally desirable to employ the herein described apparatus and manufactures, but it is to be understood in carrying out the objects of my invention, less than all of the different means, mechanisms, and manufactures herein described may be employed for some uses, or parts only may be employed, or other mechanisms and manufactures similar may be employed and substituted, and while the preferred forms of my invention are shown, it is to be understood that many of the structural details and steps resorted to may be varied and many changes in details and steps resorted to without departing from the scope and spirit of my invention, nor do I limit myself to the specific devices, 15 manufactures and methods shown, although I believe themespecially suited to the ends to be attained by my invention.

The accompanying drawings are largely diagrammatical andare not to be considered as working drawings of the invention, but merely as illustrations of the principles of the invention. Many parts of the apparatus are omitted from the particular figures and in particular figures different planes are taken and portions forward of the planes are indicated and the juncture of the planes is not always indicated, for the purpose of clearness of illustration of the invention without the multiplication of drawings. Terms used in the singular imply the plural and vice versa when the context so indicates.

In the accompanying figures of the drawings, illustrating a form of my invention and forming.

a part hereof, and in which the same reference numerals and letters indicate the same or corresponding parts:

Fig. l to Fig. 13 inclusive, sheets one to three, illustrate the sending apparatus Sheet one 4.0

Fig. 1 is a sectional end elevation on line A of Fig. 13, looking towards the left hand end as illustrated in Fig. 11.

Fig. 2 is compose-d of an upper and lower part. The lower part is a plan of two keys of the keyboard and the front wall, and the upper part is a section with the face or front wall removed.

Fig. 3 is a vertical section of a portion of the keyboard on line H of Fig. 8.

Fig. 4 is a side elevation of a portion of a commutator disc. v

Fig. 5 is a section of the same on line J of Fig. 4.

Fig. 6 is a plan of the periphery of same.

Sheet two Fig. 7 is a longitudinal section from top to bottom through the left end of the apparatus with the front keyboard walls removed.

Fig. 8 is a similar section as regards the right side, while the left side, left of the broken line, is a front elevation of the middle of the apparatus.

Fig. 9 is a section of the friction drum of the commutator disc, on line K of Fig. 10.

Fig. 10 is a side elevation of the same, partly in section on line L of Fig. 9.

Sheet three Fig. 11 is a sectional plan at different elevations. The upper part, beginning at the left, is on lines B, C, D and F of Fig. 1, the front walls are shown in section on line E of Fig. 1 and the lower part is a skeletonized plan.

Fig. 12 is a plan, partly in section, to the right of the broken line. This indicates the commutator disc and brushes below line F of Fig. 1.

Fig. 13 is a sectional plan on line G of Fig. 1.

Figs. 14 to 22 inclusive illustrate the printer; sheets three to six inclusive.

Sheet four.

Fig. 14 is a sectional plan on lines M and N of Fig. 1'7.

Fig. 15 is a side elevation of an escapement unit.

Sheet five Fig. 16 is a sectional end elevation on line P of Fig. 14.

Fig. 1'7 is a sectional end elevation on line Q of Fig. 14.

Sheet six Fig. 18 is a side sectional elevation of the manual printing crank end of the apparatus,' taken Sheet seven Fig. 23 is a diagram of the electrical connections of the sending apparatus.

Fig. 24 is a diagram of the electrical connections of the printing apparatus.

Sheet eight Fig. 25 is a diagram of the electrical connecnections of the sending apparatus when multiple high frequency currents are used.

Fig. 26 is a diagram of the electrical connections of the printer when multiple high frequency currents are used.

The sending apparatus illustrated in Figs. 1 to 13 comprises twelve sending discs with commutators on their peripheries adapted to send alternating current to line. These commutator discs I are mounted to rotate freely on shaft 2. Attached to one side of the disc is retracting spring 3, and to the other side gear 4 through a friction drum 5, illustrated in detail in Figs. 9 and 10.

Fig. 1 is a sectional elevation on line A-A of Fig. 13. Fig. 11 is a sectional plan of the left end of the apparatus. Contact-breaking magnet 20 is shown on a plane approximately indicated by line B of Fig. 1. The clutch magnet 9 is shown on the plane indicated approximately by line C of Fig. l, and. the clutch arm and crowbeak-sector system on the plane indicated approximately by line D. The front portion is about on line E of Fig. 1.

Gear 4 is driven by spur gear 6, mounted to rotate freely on shaft I. Slidably feathered to shaft I are clutches 8. spur gears 6 when throwninto engagment by clutch magnet 9, through hell crank lever I0.

- Clutch magnets 9 are supported by anarm to rear wall M of framework I2. A table stud of the arm II supporting the clutch magnets carries contact springs I3, arranged so that the contact is made when the magnet is energized and broken when it is de-energized. Attached to bar I8 of. hell crank armature lever I is a spring which tends to keep the clutch open, but which is overcome when the magnet is energized.

A description of the sequence of operations of these magnets, circuits, springs and. mechanical parts will be given later in connection with diagram 23.

A crowbeak ratchet composed of arm I4 and beak I is mounted on a stud in framework I2, adapted to rotate in a vertical plane. 'A small springat its axis tends to force arm I4 down- Ward. Beak I5 is hinged to bar I4, so that its point is free to move towards the axis of bar I4, but a small spring acts in opposition to movement in that direction, the small spring being at its axis. The beak cannot move away from the axis of bar I4, by reason of shoulders at the axis of beak I5.

A table arm I6 extends from the framework towards the clutch, and carries sector H, which is mounted on a stud in I6 to rotate partially in one direction or the other in the horizontal plane. The inner arm of lever arm I8 is bevelled to a median line, which pushes the apex of sector I! back and forth as the clutch operates. As seen in Fig. 11, the clutch is open, Sector IT is held These clutches drive in the normal median position by a small axis spring. Whenbar I8 moves to close the clutch 8, the apex of the sector is carried along with it until bar I8 passes it, when the sector flies back to normal. When I8 opens the clutch it carries the apex along in the other direction until it passes it and the sector flies back to its normal median position.

The point of beak I5 rests on sector IT at times in the cycle of operations and at other times on table I6.

Figs. '7 and 8 show the three positions assumed during operation. When the apparatus is cleared to begin functioning the clutch is open, the sector is in the median position and the crow beak rests on the sector as shown in Fig. 8. As shown in Fig. 7, right hand example, the clutch is closed. This drives the fan side of the sector to the left, sliding under beak I5, but not letting beak I5 fall to the table I6. These two examples show the clutch open at the outset and the clutch closed to operate the spur gear 5, the gear 4 and the disc I. When disc I is stopped by a key, clutch magnet 9 is automatically deenergized and the spring of arm I8 throws the clutch out of engagement. This causes the fan side of the sector to move to the right, which per- .mits beak I5 to fall to table I6. As this takes place arm I4 closes switch I9, which completes a local circuit to energize the clutch magnet of the next disc unit. Beak I5 is so hinged to bar I4 that it may be forced back in the position seen in the left example of Fig. 7. In Fig. 7 the'left The rows of keys number from left to right. hand example of beak and clutch have operated The illustration shows thirty six keys in a row. and the clutch has been disengaged. All the This only applies to rows of seat numbers. Othunits will assume this position when the whole er rows have a fewer number or a greater num apparatus has functioned. The right hand exber of keys as required, although where a great ample of Fig. 7 is in operation, and the example er number is required it is better to have alterin Fig. 8 is awaiting operation. It is in the posinative rows as in the case of H and HH. In

tion assumed after being clearedby manualop- Fig. 8 rows HH and H are shown, while the eration from the position in the left hand exshort row in which the keys are marked R, L, C, ample of Fig. '7. 1, 2, 3, 4, .5, 6 and 7 indicates locations, right,

Contact breaking magnet 20 is attached to the left, center and sections 1 to 7. I

framework by a lug, and standards 2| carry In rows A and AA a key will be noticed at the armature 22 on lever 26,. making contact with top marked SK. This stands for skip, and pillar 23 for the line alternating circuit. The. causes the disc to stop at the first segment of breaking of this contact breaks the line. Ratchthe commutator and transfer the functioning to et arm 24 is pivoted to lugs in' the framework, the next disk. The reason for this is that no and has a tooth, 25, which engages the end of ticket could be for more than onerow, and armature lever 26. Thus when the magnet is when the ticket is printed the space of the row energized bar 26 is drawn in and caught by the skipped is left blank. The number of seats in tooth and contact at pillar 23 is permanently the row is also provided with a skip key. Where broken even after magnet 20 is de-energized. the number of theatres is greater than can be Foot 21 of arm 24 rests on universal lifter bar 28, contained on one printing wheel, a second will extending across the whole apparatus, and it be supplied with skip keys for the two rows of supports all the feet 21, which are depressed by theatre keys. i springs 29. Spindle 30, rotating in the sides of The keys, as 5|, are mounted on plungers as the framework and in standards 2| carries cams' 5 2, with notch 53, peg stop 54 and spring 55, 3| affixed to it. Manually operable crank 32 is as detailed in Figs. 2 and 3.v The section of the affixed to spindle and when it is rotated it key at the end is a flat rectangle.

lifts all the feet 21 and arms 24 and allows The keys are journalled in three walls, the front springs 33 to draw back the armature lever and or face wall 55, the working wall 51, parallel to re-make the contacts at pillars 23. This manthe face wall and the rear wall, 58, a cylindrical ual operation of crank 32 takes place after the wall curved about the periphery of the discs formechanism has functioned in order to clear the about 145. One keyof each row except the skip levers for the next operation. rows, in which case the skip key is used, is pushed Universal bar lifter 28 has attached to it arms in. They are automatically caught and held in. 34, which extend down and under crowbeak bar Disc I carries stud 59. When disc I rotates I4 and lift the crow beak levers at the same time counter clockwise, as seen in Fig. 1, stud 59 will ratchet 24 is cleared. This brings beaks I5 up presently encounter the key heel which has been to rest on sector I1, as shown in Fig. 8. This pushed in. 'Meanwhile in rotating a number of breaks contact I9 on the local clutch magnet alternating impulses are sent to line. If the top circuit. Contact I3 is broken by the de-energi key is presented only-one impulse goes to line, if

zation of the clutch magnets, which breaks the the bottom key, thirty six impulses or eighteen line circuit. alternations. When the disc is stopped a pro- Shaft 1 on which the slidable members of the 'longation of the final impulse goes to line, which clutches are mounted is driven by a motor 35, functions to cut out the disc and set the next disc with pulley 36, belt 31 and pulley 38 on shaft 1. Shafts 2 and 1 are fixed in standards 39 which extend from the floor 40 to rear wall 4|.

Disc I bears a commutator 42' peripherally, with side annular rings 43, 44, connected to alternating segments as 45-46, as seen in Figs. 4,

in operation.

The prolonged impulse throws the clutch'out of engagement, when spiral spring 3, which has been slightly wound up during the rotation of the disc throws the disc back to its initial position, stud 58 of disc I striking standard. 6|, which sup-.

5 and 6. Insulation 41 is placed between the ports wall 58. segments of the commutator. Brush 48 rests on Motor 35 is started by manually closing switch the periphery and the segments pass under it, 62. Switch 63 throws in the main line. When while brushes 49, 50 contact with annular rings the motor is running and the line is thrown in 43, 44, thus supplying current of opposite phase,. spur gear 6 drivesgear 4, but disc I is prevented and brush 48 thus passing alternating current from rotating by mechanical stop 64 engaging to line of a frequency depending on the width of lug on disc Switch 63 closes the line inthe segments and speed of disc I. directly through closing a local battery circuit A-keyboard with keys as 5|, in twelve rows, which energizes clutch magnet 9 throwing clutch is provided. The rows are as follows: into engagement and Closing main linep 4 has spring 66 and flange 61. The spring draws it inward. When pulled out manually it releases disc I. Stop 64 and lug 65 are bevelledso that 'when spring 3 drives disc I back, stop 64 again engages lug 65 automatically.

. Name of theatre, as Broadhurst;

. Price of ticket as $4.40;

. Year of sale, as 1929;

. Day of month, as 21;

Month of year, as March;

Day of week and time of day, as Thursday at the bottom of Fig. 1. Stop arm 64a is pressed Evening; against stop by spring a. It is pivotedin lugs 7. Number of seat in row, as 101;

8. An alternative number as 24;

9. Letter of row as HH;

. An alternative letter as H;

. Side of theatre, as Right;

. Floor, as Orchestra.

turned by acrank manually depressing 64a below stop 63 and allowing discs tofturn.

Friction drum 5 is illustrated in detail in Figs. 9 and 10. Cup 68 is'fixedto disc I.

tates freely on shaft 2.- Gear 4 which has a boss on the floor and is fixed to spindle 66a, which is Disc I ro-- Supplementary stops for all the discs are shown hub 69 rotates freely on shaft 2. Amazed to boss 69 is disc Ill, which rubs the inner face of cup 63. Disc Ill has four wings as II, cut through and bent. down. The lower ends rest on'the face of disc I; the portions marked l2 in Fig. 10. The wings are of springy material and force faces til and I together. While gear ii rotates and disc I is free to rotate, the pressure of wings III is sulficient to carry disc I along, but if disc l is stopped, wings ll continue to rotate along with boss 59 and gear 4i, and-rub over the face of disc I, starting it instantly it is released. As there, is only a small load on disc I, wings II need press only lightly on disc I.

In order to hold the keys in the operative position when they are depressed and to release them singly or-,in totality simultaneously, means are provided as shown in detail in Figs. 2 and 3. The lower part of Fig. 2 is an elevation of the face wall 56 and two keys with a wing thumb piece. The upper part of the figure is a section with the face wall removed. Key plungers iii, M are in idle position. Key plunger 75 has been depressed to the operative position. Latch levers iii, ll,

are provided, pivoted on stud screws Ill, lit, lk

Mounted on stud screws also are leaf springs 32, 83, 8% which force the latch levers against the sides of the key plungers. When the key plunger is depressed, its notch 53 is engaged by the latch lever, and its end, as 85, is held in the path of stud 59 of disc I, and brings disc 5 to a stop when stud 59 reaches end 85. In order to return a single key, as 86, to idle position, wing thumb piece as 3'3 is provided. Through axis stud it is affixed to a latch lever and may be manually operated in opposition to latch lever spring to lift latch lever out of notch in plunger and allow spring 55 to return plunger to the idle position.

Sliding in guides as fil on the inside of the face wall 55, are a set of combs as 88, terminating at the bottom each in a bar as 59, sliding in slots in walls 56, Eat, the outer end of which, 95, serves as a key for the manual depression of the whole comb, in opposition to spring'bl which normally holds the combs in the upper position. The comb 88 has teeth as 92, 93, 95 which engage the ends of levers as i9, 85, ti. When lever it falls into notch 53, tooth 9% stops lever end ti and the depression of key 96 will clear the key similarly as would the operation of thumb piece In order to clear all the keys at once, a universal depressing bar 55 extends across the apparatus and bears on the inner ends of bars 89. Universal bar 95 is hinged by arm 95 to a pivot in lugs 91. bar 95 and are pivoted in lugs 99. Three of these are sufiicient, one at either end and one in the middle. Cam shaft I III] extends across the apparatus and has cams IDI and handle crank I02. 'When I I12 is rotated manually cams I III strike arms 98 and depress the universal bar, carrying down all the combs and freeing all the keys. Distance piece. I03 extends from base 6| of wall 58 to wall 51 at the bottom. The walls are attached at .thetop to top plate I04 of the.

Depressing arms 98 lie on universal ticket lifts I58 up electrical contacts at the other end, iI3-I M are made, being in series with switch 63 which would not close its circuit unless Ilia-I MI was also closed. It is thus necessary to introduce a ticket to start the apparatus.

In order to deface the ticket, punch I I5 on the end of lever M6, pivoted in lugs Ill, is opposite a hole in the base plate I I I, and it is driven down through the ticket. Cam I it on shaft ltd drives lever lit down when shaft I00 is rotated manually to clear the keyboard. Shaft we is journalled in side I05 of framework, and in lug H9- near side 62d of framework I2.

The diagram, Fig. 23, shows the electrical connections. In the diagram the first unit at the right has been operated, the second unit is in operation and the two units to the left are awaiting operation. Only four units are indicated, but as many more as desired may be inserted, preferably between units two and three. The diagram, generally speaking, is viewingthe apparatus from the rear, looking towards inside of keyboard. The operations begin on the right of the figure and work towards the left.

To operate the apparatus the following steps are taken. A ticket is inserted in slot 955, thus closing contacts II3--I I l. The motor 35 is turned on by switch 62. Shaft I now begins to rotate idly. All the clutches 8 are open. The operator closes switch 53. This completes local circuit Adi. It comprises local battery or other source of direct current, B22, magnet A9 and contact I25 at armature of magnet ears. The initial position is best seen. at B525, as Aafll as shown has already functioned. The completion of circuit Aai energizes clutch magnet as and this attracts armature, At t. is best seen at Git and the completed position at Bill. The drawing down of armature AMI! completes main line circuit A2, but it cannot yet send impulses to line as disc AI has not started to rotate. Contact I25 completes the line circuit. The depression of Alt causes clutch Ail to engage, as best seen at B8. Spur gear At rotates and drives gear Ad, but as disc AI is held by stop t l-55 it cannot rotate. Take-off brush 48 rests on insulation at the initial point.

Line circuit. A2 starts at line batteries AI25 and M26 with their opposite poles to earth, connected by brushes 4-9, to commutator annular rings of disc I, thus supplying current of opposite sign as the disc rotates. Lead A goes to contact I24 where it is completed by armature All). It then goes to magnet Aa20 and from thence to line.

At this point the apparatus is in readiness for operation, the line being earthed at the outlying station. The functioning begins when stop 64 is manually released. Disc AI begins to rotate and sends alternating impulses to line which operate the outlying printers initial typewheel. When disc I is stopped by stud 59 striking a key heel set for that purpose, a prolongation of the last impulse is sent to line.

Magnet Aa20 is so wound that the alternating impulses do not affect it, but when the impulse is prolonged the magnet functions, and draws down its armature Aa2lJ. This armature is caught by ratchet A1124, and remains in that position until cleared manually at the close of the operation, by crank 32. The depression of armature Aa22 breaks contact I23 and opens circuit AaI permanently. This de-energizes magnet A9, which permits clutch A8 to be disengaged and breaks contact I24. Thus the line goes dead by The initial position from batteries BI25, BI20.

a dead space on the line momentarily.

When armature AIO. is released it allows arm I8 of bell crank I0 to pass to the left as seen in Fig. 11. This causes the fan part of sector IT to be pushed to the right, and allows crow beak I5 to fall to table I6, and thus close contact I9.

The sector is not illustrated in the diagram, but crowbeak I 5 and arm I4 are indicated in the low-. eredposition making contact AI9.

The closing of AIS completes local circuit BbI, which passes through direct current battery I21, contact BI20 and clutch magnet B9. It energizes B9 and causes contact I29 to be made, setting up the main line circuit B2, which derives current This circuit passes on through brush B48,'lead B to contact I29, magnet B2220 and thence to line. The line remains dead as disc BI does not rotate until clutch B8 engages, which is momentarily after the making of contact I29. Upon disc BI rotating, alternating impulses pass to line until the disc is stopped by a key heel, when aprolonged impulse results. In the illustration of the Figure 23 the unit B is in operation and unit A has ceased to function. When the discs are stopped by the key heels the friction drum 5 between disc I and gear 4 permits shaft I and spur gear Ii to continue to rotate gear 4 while disc I is held at rest.

When disc BI is stopped by a key heel, a prolonged impulse goes to line, which energizes magnet Bb20, and attracts-armature B1222, breaking contact BI28, while 31122 is locked up by ratchet B1224. This breaks circuit BbI which de-energizes magnet B9, and frees B I 0, which then takes the position shown in the diagram by All], breaks contact I29, which makes the line dead, and disengages clutch B8. The fall of crow beak B15 tact CI3I.

,impulse energizes magnet Dd20.

makes the contact BI9 and sets up the local circuit CcI. 7

Local circuit CcI includes contact BIS, local direct current battery CI30, magnet C9 and con- It energizes C9 and completes line circuit C2 through contact I32. Brush C48 draws alternating impulses from batteries CI25, CI26 which proceed through lead C, contact I32 and magnet Cc20, and thence to line. The subsequent closing of clutch C8 starts disc CI which sends the alternating impulses. When a key heel stops disc CI, the prolonged impulse energizes magnet C020, breaks contact CI3I, armature C022 being locked up by catch C024; When local cireuit CcI is broken by CI3I, magnet C9 de-energizes, line circuit C2 is broken at I32 and local circuit ,Ddl is made by the fall of crow beak CI5 making contact CI9. Clutch C8 is'disengaged.

Local circuit DdI includes contact CI9, direct current battery I33, magnet D9 and contact DI34. This energizes magnet D9 and sets up main line circuit D2 by making contact, I35. Circuit D2 starts at batteries DI25, DI 26, thence through brushes of disc DI to lead D, contact I 35, magnet Dd20 and thence to line. The closing of clutch D8 starts disc DI and sends alternating impulses to line. The prolongation of the last Contact DI34 is broken, and armature Dd22 is locked up by catch Dd24. This de-energizes magnet D9, breaks contact I 35 and makes line D2 dead. This completes the cycle of functions, as crow beak DI5 has no function to perform in energizing a further local circuit. The operator now prepares the apparatus fo a new cycle by opening switches 62 and 63. Crank 32 is turned which clears the-ratchets of the line -magnets and prepares contacts for the local circuits, returning the parts to the positions indicated at C9, CIO and B1220.

The operator then rotates crank I02 which clears the keys and defaces the ticket at I05,

which is then withdrawn.

In'case a ticket such as HH24 has been printe and the next ticket is to be the adjoining one at EH26, the operatordoes not clear the keys with crank I02, but clears key 24 with thumb piece 81 and sets key 26. He leaves ticket 111-124 in slot I05 and causes the machine to operate as before. At the conclusion he defaces ticket EH24, removes it and inserts ticket EH26 and defaces it by a turn of crank I02, which only moves combs 88 idly as they have already released the keys.

The line I36 is superimposed on telephone line I38 byapparatus I39, well known in the art. Telephone I3I enables the operator to converse with the printer operator to ascertain what tickets are wanted,'and to have the printer'setting read back to him before printing to avoid any mistakes.

The apparatus thus functions to send selected groups of signals to line, each group comprising a selected number of alternating impulses and a prolonged impulse at the end and a dead space. These impulses and spaces are used to operate the printer at the outlying station.

The printer is illustrated in Figs.' 14 to 22 inelusive. I

The printing machine consists of a series of type-wheels with type on their'peripheries cortion, supported by the base, but bearing a fixed type, II, which indicates the number of the outlying station. remains in its station, this number does not need to be succeeded by any other. It appears on all tickets. Other stations, of course have different' numbers on this partition. Another partition, 204, is marked with the initials E. P., T. P., To., and A. O. This stands for the words Established Price, Tax Paid, Total Price, and Admit One. This reading matter is the same for all tickets, and this portion is, accordingly, permanently fixed.

Typewheel 205 is marked 4-, .40 and 4.40. These figures stand for $4.40, $0.40 and $4.40, coming opposite the. words Established Price, Tax Paid and Total Price of the partition 204, respectively. Where the price is $3.00 or less and no tax is paid, the figures opposite Tax Paid are omitted. Attached to typewheel 205' is gear 206.

Typewheel 201 bears the year date, as 1929. To this is attached gear 208. The year day is usedbecause of changes at the .end of the year, and because a dozen years or more may be placed on it to avoid frequent changes of this wheel.

Typewheel 209 bears days of the month from 1 to 31. Attached to it is gear 2 I0. These wheels As once a printer is installed it The remaining portion of the ticket from this point on is the coupon to be torn off at the theatre door and retained by the patron. It bears duplicates of price and dates, and has additional data.

The typewheels bearing duplicate matter are driven by the same shaft that drives the original, and thus do not require additional sets of keys on the sender.

Typewheel 2 Mi again bears the year date, 1929. To it is attached gear 2th.

Typewheel 2E6 bears the day of the month again, and attached to it is gear 257?.

Typewheel 2w bears the' month again, and attached to it is gear 2H9.

Typewheel 22d contains the days of the week, not used before, and also distinguishes between gatinees and evenings. Attached to it is gear .Typewheel 222 bears the figures 10." This is a number corresponding to the name of the theatre as on typewheel 28H. Thus theidentification of the theatre is made on the coupon after it is detached, data which needs to be familiar only to the employee of the theatre. Gear223 is attached to typewheel 222.

Typewheel 22d bears the prices, as $4.40, indicating the total price. It is operated in conjunction with typewheel 205. Gear 225 is attached to typewheel 224.

Typewheel 226 bears the number 101, indicating a seat number. On this wheel are numbers from 101 to 135, usually center section numbersin a theatre. Attached to 226 is gear 221.

Typewheel 228 bears figure 21. This is also one of a set of seat numbers, ranging from 1 to. 35, usually side section numbers. In printing a ticket either typewheel 226 or 228 is used but not both, the unused one being skipped by the skip key. Gear 229 is attached to typewheel 228.

Typewheel 238 carries letters, H. H. This is a row designation which runs from AA to ZZ. Gear 23! is attached to typewheel 239. v

Typewheel 232 shows letter l-I. This is a row designation which runs from A to Z. In use either 23d or 232 is used but not both. The one not used is skipped. For these skipped wheels, the periphery at the initial point bears no type, and leaves a blank space on the ticket.

Gear 286 is attached to typewheel 232.

Typewheel 2% shows word Right. This is a location by sections or aisles. Gear 23% is attached to typewheel 234. r

Typewheel 236 bears the designation Orch, being afioor designation, as orchestra, balcony, etc., attached in gear 231.

The gear and typewheel units are mounted to rotate freely on fixed shaft 238, set in standards 239, 2th in the base.

Mounted to rotate freely on shaft 2d 0, fixed in standards 2 l22d3 are seventeen gears as M l, to engage gears 282, 2%, 2%, 2m, 202, 2%, till, 2m, EM, 223, 225, 221i, 229, 236, 282-3, 235 and 2st.

These gears all engage gears 2 3d which in turn are engaged by gears of equal number mounted to rotate freely on fixed shaft 265,,

mounted in standards Nit-2 3i, which standards also serve to journal rotating shaft 2%, with grooved pulley wheel 249 and pulley cord 258.

Script wheels, partitions and gears 25i to 28? inclusive correspond to type wheels, partitions and gears 2M to 2371 inclusive. The script wheels and partitions are similar in size to the type wheels and partitions, and bear in readable script the same symbols as are borne by the type wheels and their partitions reversed to print from. The symbols on the script wheels and their partitions are visible through a window in the top of the cover, indicated by dotted lines 288 in Fig. 14, being above the plane of the paper of this sectional plan.

The gears amxed to the script wheels, thev intermediate gears 2M, and the gears aiiixed to the type wheels are all of the same size. Thus through window 288 may be read the data which will be on the ticket when printed. If any mistake is made by the operator of the sending ma chine, it becomes obvious to the operator of the printer before printing, and the printer may be cleared and the error corrected before printing.

Beneath the script wheels are seventeen gears, as 289, somewhat larger than the script wheel gears, but not necessarily so. They are attached to the shaft by friction drums 36i as seen in Figs. 21 and 22 in detail.

Shaft 2 38 is driven by pulley 2M, cord 2% and pulley 260 on shaft of motor 2%. Motor 291] runs continuously during operation. It is turned on by switch handle 262 closing switch contacts at 293 when the machine is to be operated, and is turned off manually afterwards.

Gears 289 would rotate script and typewheels continuously if not prevented, but when a typewheel and script wheel are stopped, shaft 248 continues to rotate, and will drive anyof the wheels immediately they are released, through the friction drums 46!.

In order to stop the typewheels at the proper locations so that the selected ticket may be reproduced, a set of twelve escapement units are provided, six on one side and six on the other.

A detailed side elevation of the escapement unit is shown in Fig. 15. There are twelve units one for each row of sender keys. Some of them 7 control two typewheels that are duplicates, as the date and price on ticket and coupon. Twelve shafts are controlled by the escapement units, six at one end and six at the other, in six lines, two units being at the outer ends of a pair of shafts in line.

Escapement shafts 294, 295, 296, 291, 298 and 299 at the front or lower end of Fig. 14 are respectively in line with shafts 386, 3M, 3&2, M3, 9% and M5 at the rear end.

The escapement shafts 294 to 3935 inclusive have gears afiixed to them, driven by the gears of the typewheels and of the same size. when the escapement shafts are stopped the typewheels and script wheels are also stopped.

Shaft 29d has gear 294G, which controls typewheel 226, bearing seat numbers, as FL. This is effected through gear 22'! which engages gear 29 16.

Shaft SM is in line with shaft 296, and has gear 368G, controlling typewhel 236, indicating floors, as Orch. This control is effected through gear 2% on typewheel 23d. Shaft 3% is journalled in standards stew and iilldWii, which are attached to the side wall but are brokenofi in the drawing, as they attach above the plane of the paper. Shaft set is similarly Shaft 30| is in line with shaft 295. Shaft 3'01 ($4.40) "through gear 225 on the coupon part of the ticket.

Shaft 302 is in line with shaft 296. Ithas gear 302G which controls typewheel 234 (right).

through gear 235. Shaft 302 is journalled in standards 302B and 30232, the latter not shown, which extend to the floor. Shaft 296 is similarly journalled.

All the remaining escapement shafts are journalled in standards which extend to the base or floor of the machine, and which are bent and offset to reach the floor without interfering with other members. These standards are mostly broken away in the drawings for the sake of clearness.

Shaft 291 controls two typewheels bearing the day of the month, and shaft 303 in line with it controls seat number typewheel 224 (seat number 21). Y

Shaft 298 controls two .typewheels bearing the year, (1929) and shaft 306 in line with it controls typewheel 220, (Thursday evening).

Shaft 299 controls typewheel 20| (theatre) and typewheel 226 (10, number of theatre), and shaft 305, in line with it, controls typewheel 232 (row letter H). I 1

These seventeen forms of changeable data are thus controlled by twelve escapement units and shafts.

The escapement units are similar although placed at different angular attitudes asregards shaft 238.

As seen in Fig. 15, framework of unit 301 is attached to standard 308 which may be affixed to wall or base.

Frame 301 carries magnet 309, positioned perpendicularly and magnet 3 0-, positioned horizontally. Escapement arm 3 is pivoted in frame 3|2, and has cross bar stop end 3|3.

A pair of escapement wheels are provided, affixed to escapement shaft as 295. They are provided with teeth. The teeth of one wheel are staggered with respect to the other by the amplitude of half the pitch of a tooth. When the arm 3| moves back and forth from one to the other, the teeth being driventowards the bar stop end 3|3, the shaft rotates by an angle equal to half the pitch of atooth at each movement, or a whole tooth on a stroke back and forth. Magnet 3|0 is a polarized magnet and so arranged that when the arm 3| is drawn to one side it remains there until drawn to the other side by alternations On the prolonged impulse the arm 3 remains Shaft 30| is jourwas earlier.

spring- 323 at the moment arm 3H and stop 3|3 where it was drawn. When the time for clearing the escapement wheels comes, local current is applied to magnet 309, being direct current. Magnet 309 being energized, stop 3 I3 is lifted with arm 3|'| from whatever tooth it happens to be in, and the escapement shaft rotates, in a counterclockwise direction as seen in Fig. 15. Arm 3| is pivot'ed in frame 3| 2 which in turn is pivoted in standards 3|6 3|1 on spindle .3l8, while end 3|9 of arm 3 carries armature 320. Magnet 309 attracts this and thus lifts arm 3| Magnet 309 3 on the escapement wheels.

In order to stop all the escapement wheels a l the initial point, irrespective of how many teeth have. escaped, a contact breaker composed of spring leaves 322-323 is provided' The circuit of magnet 309 is in series through this breaker.

Cam 324 is fixed to the shaft 295. As it rotates after the shaft is freed by the lifting of lever arm 3| I, it-presses down contact leaf spring 323. A space free of teeth is provided on the escapement wheels, beginningat point 325 and extending to high tooth 326. On the type and script wheels a similar blank space is provided, no letters appearing on that space.

Leaf spring 323 and spring 322 and cam 324 are so adjusted that contact at point 321 is broken just after point 325 on wheel 3|4 has passed stop 3|3. The de-energization of magnet 309 there-, upon, allows spring 32! to retract arm 3| and stop 3|3 strikes the toothless portion between'325 and 326. When high tooth 326 strikes stop 3|3 the shaft stops. Similarly all the shafts are thus stopped at. the initial point of the high .tooth.

The high tooth is provided in case arm 3 does not descend quickly enough. The wheel 3|4 must then stop at the initial tooth whether the magnet has released arm 3" in time or not. Cam 324 serves an additional purpose in that it dampens the momentum of the shaft towards the end of the rotation, so that the shaft is rotating much more slowly when point 325 isreached than it Cam 324 slips off the end of leaf To accomplish the automatic succession of one escapement unit after the other, a series of twelve contact make and break magnets are provided, as 328. Also a set of twelve units of ratchet magnets, 329-330 and a thirteenth unit of the same.

Magnet 328, a plan of which is seen in Fig. 14, a side elevation in Fig. 16 and an end elevation in Fig. 18, is comprised of base plate 33| affixed to floor 332 of the machine. Riser 333 supports magnet 334, and pillar 335 serves as a pivot for a double pendant arm, 336331 working as a unit. One arm makes contacts 339, 340, MI and the other the two contacts 342, 343 when the armature is drawn in, breaking the contacts 339;

340, 34L When the magnet is energized the catch 344 locks the armature in that position,

This is accomplished by means of crank 395, affixed to shaft 348 journalled in side 391 of the main frame and standard 338 at the other end mounted on base 332. Fixed on shaft 335 are cams 399, one for each catch 399. When the crank is rotated these cams depress catches 393, which are pivoted in lugs.359, and press them down against the force of spring 35l. This frees the bottom end of 335 and it is drawn back to its initial position by spring 352, breaking contacts 3 l2-3 l3 and remaking contacts 339, 349, 3 31. This resetting or clearing takes place after the function is complete in order to clear the machine for a new operation.

Operated in conjunction with units 329 are units 323-339, the electrical connections of which will be described later. When magnet 353 of unit 329 is energized it attracts armature lever 354, mounted on lugs 355 set in side wall 313, and restrained by spring 358, which is overcome by the magnets action. When the armature is attracted an electrical contact is made from the armature through leaf contact 351. This energizes magnet 358 of unit 339, which has as an armature a bell crank lever 359, pivoted at 359. Pegs 333i, 332 limit the movement of armatures 359, 359.

When contact 351 is made, magnet 358 attracts the armature, overcoming spring 363. This throws catch 334 against the end of armature 354, which remains locked up, even after 353 is de-energized, until the circuit of magnet 358 is broken at another point, which unlocks armature 354 and breaks contact 351.

A contact block 359 on armature 354, but electrically isolated from it, serves to close an elecmotor by motor switch 292, the units 328 having first been cleared by the manual operation of crank 345. When the motor is started the friction drums dfii tend to rotate the script wheels and type-wheels. the high tooth 326,however, prevents. The sending operator is in telephonic communication with the printer operator and when the sending operator announces that his machine is set and ready to transmit, the printer operator closes line switch lever 331 against spring 368, lever 331 being pivoted in side wall 369. In the normal or open position of the switch lever it connects line 'to earth. When the switch 361 is closed, this contact is momentarily broken, the line is connected to the apparatus and earth is reached after passing through the apparatus.

When lever 361 is in the dotted line position 319 seen in Fig. 14 it connects line to apparatus. When closed, lever 381 is locked by bell crank lever catch 316 in opposition to spring 3M, and

cannot be manually released. When magnet 313 is energized by a local circuit, which happens i only after the whole apparatus is set for printing, the lever 361 is released. When necessary in case of an emergency, lever 391 may be tilted out of the plane of the paper and'may thus be freed from 31H. If this occurs during operation it leaves some of the magnets locked upl They may be cleared as described later.

The thirteenth set 329-339 does not employ the contacts 363, 365, 396. The thirteen sets are arranged on the wall 313, but if desired may be placed under the gears 24 3. Platform 314 is attached to wall 399 and carries contacts 315, cutting the machine out of line, contacts 316 cutting it in line, and magnet 313, pivot 311 an bell crank 3H.

An emergency switch 313 closes contact 319 to clear the escapementarms 35 i, as described later.

When all the type wheels have been set the printing function is carried out. 389 is seen in side elevation in Fig. 16, section in Fig. 17, partly in front elevation in Fig. 18, and indicated in plan by dotted lines in Fig. 14., being above the plane of the paper. This arm is afiixed to two plunger rods 38!], 332. The'printing arm is of H shape, one staff of theH, 333, extending over the type, and the cross bar of the H reaching to the portion connected with the plunger rods. fiar 393 is hinged at 394 so that it can swing up on arc indicated by dotted line 385, Fig. 17. A thumb plate 393, rotating on an axis pin 391 when turned parallel to bar 383 permits the latter to be raised. The ticket may then be inserted in grooves in the bar 393 to be printed. When the thumb plate is turned parallel to the cross bar of the H it holds the bar 383 solidly in the printing position.

Two grooves are shown in bar 383; one is for the ticket and the other for a duplicate which may be printed by the insertion of a piece of carbon paper between the two.

A masking plate, stencil or matrix 388, Fig. 20, is fitted over the ticket, the type appearing in the apertures as 389. The under side of bar 383 may also be routed out in the portions corresponding to those of the masking plate between the apertures and the edges, as 390. Thus no pressure is applied to any but the printing surfaces, and the rest of the ticket is not smudged.

When the printing lever is pressed down the printing is efiected by an inked ribbon 39l, similar to a typewriter ribbon, which is drawn across the type slightly between printings. The ribbon is in the form of an endless belt. Its upper stretch across the type is carried by rollers 392,

393. It'passes downfrom 393 to roller 394, be-

ing drawn down by pressure rollers 395, 396, mounted on standards 391, 398, 399 set in the base. Roller 399 is fitted with gear 400, which is engaged by gear 40! on shaft 992. Gear 40! is stripped of teeth for half its periphery, so that the ribbon does not move during the printing stroke but moves at its conclusion, through the latter half of the rotation of shaft 303. From rollers 395399 the ribbon proceeds under roller 3%, then along the base through passage holes in the partitions and standards again to roller 395 and'then up to the starting point 392.

The printing impression is efiected by rotating crank 993, affixed to shaft 492 for one revolution. Shaft 992 is journalled in wall 369 and standard 399. One side of clutch 99 i is afilxed to shaft 992. In line with shaft 392 is shaft 395, journalled in standard 399 and wall 991. The end of 595 next to 592 carries the driven member of clutch Mi l. Clutch 999 normally stands engaged, through clutch lever 993, pivoted in standards 359, M9 in the base being drawn A printing arm closed by spring 41 1 extending from pedestal 2 on journal standard 406 to lever 408.

Shaft 405 has aflixed to its mitre gear 3 which engages mitre gear M4 on shaft 5, journalled in standards 6, 4", M8 in the base. Shafts 405 and H5 rotate in the ratio of one to one, shaft 405 being the driving member. Shaft 4l5 carries affixed to it cams 419-420. Plunger rods 38l, 382 work up and down in lugs 42l, 422, 423, and 424, 425, 426 extending from wall 401. Springs 421, 428 maintain the plunger rods and printer bar 380 in the topmost position. Plunger rods 38l, 382 carry arms 429, 430. When cams 4| 9, 420 are rotated by crank 403 through shafts 4 02, 405 and 5, they press on arms 429, 430 and draw down bar 380 and make the printing impression. This occurs at the end of the first half revolution of crank 403. The latter half revolution allows the plunger arms to rise and causes the progress of the ribbon to take place. Thumb plate 386 is then turned, 38 3 lifted and the ticket removed.

In order to prevent backward rotation, shaft 402 is fitted with a ratchet wheel 43l and pawl 432 and shaft 405 is fitted with ratchet wheel 433 and pawl 434.

In order to prevent crank 403 from rotating more than once at a time, cam 435 is fixed to it, inside of wall 369. In Fig. 18 the cam crank 403 is indicated in dotted lines, and a chain dotted circle indicates its radius of action. The surface of cam 435 retreats to shoulder 436. Magnet 431 has armature lever stop peg 438 and armature lever 439, retracted by spring 440. The stop end, 4 of 1ever'439 fits under the shoulder 436 and rests on the top of pillar 442, and has shoulder stop 443. In the view of Fig. 14 end 4 is preventing the further rotation of crank 403, having followed the cam surface in under the shoulder in the,

448 and peg 449. When end 4 of lever 439 approaches wall 313, its step 443 clears catch 444 which then rises so that 443 cannot return when the magnet 431 is de-energized. Once drawn towards wall 313 end 44l clears shoulder 436 and cannot impede it again until peg 450 on the periphery of cam 435 is caused to strike beam 446 of catch 444, and depress it. This depression forces catch 444 down below stop catch 443 of end 441, and it retracts, drawn by spring 440, as magnet 431 has in the meanwhile been de-energized.

This does not occur until crank 403 is partly rotated, that being made possible by its being unlocked by the withdrawal of end 441. As the cam is rotated end 44l follows it and again is under shoulder 436 at the end of the rotation. This arrangement prevents crank 403 from being rotated prematurely, it being automatically locked after one revolution until time for another printing to take place. Shaft 402 carries three commutators 451, 452, 453, with brushes for closing contacts, 454, 455, 456, at certain angles on the rotation of crank 403, as later described.

The top cover is in contours, going under type printing bar 380 at 451, over the escapement wheels on shaft 294 at458 and rising in housings at 459, 460. At 464 the top contains the window 288 for viewing the script wheels.

Fig. 21 is a section of friction drum 46l, which enables shaft 248 to drive the gears 289. Fig. 22 is a plan of the spring leaf portion of 462. Drum 46l is affixed to gear 289. Spring disc 462 is affixed to shaft 248 by tongue and groove engagement, the tongues on 462. Spring disc 462 thus rotates with shaft 248 at all times. It has four wings as 463 turned down. The bottoms of the wings rest on gear 289, and the top of the wing disc table on the inside of drum 46I. The pressure of the spring wings is sufilcient to carry gear 289 along unless it is stopped; when the wings rub over the surface of gear 289, ready to start it again when the obstruction is removed. One motor thus supplies friction drive for the seventeen gears 289.

Figure 24 is a diagram of electrical connections for the printer.

At I39 the printer current is superimposed on the telephone wire l38l40 at the sending end. At the receiving end of the line at I the printer current is deposed from the telephone line by apparatus I42 well known in the art.

Telephone line 500 leads to ear phones 50l and earth 502.

Line 503 goes to magnet 334 and from there to contact 316, made by manual operation of starting lever 361. When lever 361 makes contact at 311, the apparatus is out out, the line being earthed through lead 504 and earth contact 505.

Four units are shown, E, F, G and H, corresponding to units .A, B, C and D of the sender. Any number of units may be used, preferably inserted between units F and G. In the drawings unit E is shown as having operated, unit F about to be operated and units G and H awaiting operation.

Arm 506 of bell crank lever 336 carries two contact plates on the under side and a connection to ground. On the upper side of 331, a twin of 336, is a contact plate which makes two contacts. On the underside are contact springs 339, 340 and 341, and on the upper side contact springs 342, 343.

When arm 506 is in the position shown in unit F, circuit El exists, made .up of line 503, magnet 334E, contact 316, brushes 339340 through contact block 501 on under side of 506, lead 508L,-to

magnet 3l0E, return lead to magnet 353E, lead 509 to contact spring 34!, block 508 and lead 5| back to ground 504-505. If the line circuit is not strong enough, relays may be inserted at points or 5I2 or in lead 503.

When the alternating impulses arrive they do not affect magnets 334E and 353E, but do operate the polarized magnet 3l0E, pulling armature arm 3| I back and forth and permitting 314 and 315 to escape tooth by tooth until the selected position is reached. When the prolonged impulse occurs, on either phase, magnets 353E and 334E are energized and function. Magnet353E responds first. It completescircuit E2 as follows: Line 503, magnet 334E, contact 316, lead 5I3, arm 354, contact 351, lead 5I4, magnet 358E, lead 5l5, lead 5l0 and to earth, 504-505. When armature 354 of magnet 353E is locked up by bell crank armature catch 360 of magnet 358E, contact 351 is made and continue closed while circuit E2 exists, energizing magnet 358E, which retains 354 locked up after 353E is de-energized, and until 358E is de-energized.

When armature 354 is locked up, contact block 364 attached to armature 354 but electrically isolated therefrom, breaks contacts 365, 366.

Slightly subsequent to the action of magnet 358E, magnet 334E, energized at the same time, attracts armature 336 which is locked up by catch 344. This causes arm 566 to rise breaking contacts 339, 346, 34l, which breaks circuit El. This leaves arm 3 of magnet 3l6E in the last position to which it was drawn, and not subject to further change, holding its typewheel ready in the selected printing position.

The circuit of El which energized magnet 334E is broken but magnet 334E remains energized through the new parallel .circuit through it of E2. The breaking of contact at 364 prevents lead 5l6 from passing the prolonged impulse of the line current to 334F, which would otherwise take place through contacts 365, 364, 366 and line 5l1.

coincidentally with the action of magnet 334E and magnet 353E, local magnet A26 of the sender functions, breaking local circuit Aal, and deenergizing clutch magnet A9. All] now breaks the line at contact I24. The apparatus is so adjusted that magnet 353E locks up armature 354; magnet 334E locks up 336, and magnets Aa26 locks up Aa22 in close succession in the order named. These magnets thus have time to function before the line is broken at I24. When the line is thus broken magnet 358E is de-energized. This unlocks 354 and makes contact between 364, 365, 366. Magnet 334E is also de-energized but no function results since 336 is locked up by 344. The contact at 364, 365, 366 is made before the second disc unit of the sender begins sending alternating impulses. When Bl6 makes contact at I29 and sets up the main line B2 more time is taken than by the descent of 354. Line B2 is made up as follows; lead from sender, line,

' passes magnet 334F, through 5l8.

Circuit Fl, through magnet 3345, is similar to circuit El, and the whole unit functions as did El, which is shown as having completed its functions, 334E being locked up and block 364 making line 5l1.-

Unit G functions in a similar manner to units E and F. Unit H, however, being the terminal unit functions slightly differently, in its con-- cluding action.

Magnet 334H is energized through lead 52l, and locks up armature as before. When block 364 is dropped to contact 365, 366, lead 563H energizes magnet 431. This attracts armature 439, draws stop 44l from under shoulder 436. MI is then looked up by catch 444.

Printing crank 463 may now be manually rotated. As this occurs, stud 456 of cam 436 contacts with arm 446 of catch 444, and frees 44l, permitting it to be drawn back against cam 435, which it follows until shoulder 436 is reached at the end of the revolution.

Meanwhile the commutators on shaft 462 have come into action. Commutator 45l has segment 523, with brushes 454. Shortly after the beginning of the printing rotation of shaft 462, 454 closes local circuit 524 with battery 525 and magnet 313, which, on being thus energized frees lever 361. Spring 368 draws lever 361 which makes contact 311. This cuts out the printing apparatus and closes the line to earth for any uses of the sending apparatus.

The rotation of crank 463 causes the printing to take place on the completiorrof one-half a revolution. Shortly thereafter commutator segment 526 of commutator 452 strikes brushes 455. This completes a local circuit 521, having battery 528 and leads in parallel to the polarized magnets 3l6. This is a direct current and draws all the arms back to the left which are on the right and holds all the arms on the left which were on the left. This positions the arms for the initial position on the next functioning of the machine. As the crank 463 continues to ad- Vance circuit 521 goes dead, the commutator segment passing the brushes.

Next commutator segment 529 strikes brushes 456 and completes local circuit 536, with battery 53l and magnet 353X. This attracts armature and closes contact at 351K, and completes circuit 532 with battery 533, through contact 351X, magnet 358X and battery 533, and in parallel with the tilting magnets 369, and their circuit breakers. This includes contact 321 between springs 322 and 323 in series with its tilting magnet winding 369. When direct current circuit 532 is closed all the tilting magnets are in parallel and are energized. This causes all arms 3 'to be tilted free of the escapement teeth. The escapement shafts are in various angular attitudes. When the escapement wheel teeth are cleared all the shafts begin to rotate. As each draws near to high tooth 326, cam 324 breaks circuit 532 as regards its particular magnet. The arm 3 descends and stops the high tooth 326. When all the cams 324 have broken all the contacts 321, circuit 532 is broken. It remains alive until the last of the contacts 321 is broken. Then it goes dead, catch 366 is released and contact 351X is broken, since magnet 353X was de-energized by the passing of segment 529 as crank 463 completed its rotation.

The clearing'crank 345 is now rotated, which unlocks magnets 334E to H and the motor is turned off. When another ticket is to be printed the motor is turned on and switch 361 is turned to make contact 316.

The motor for the escapement shafts is shown at 29l with circuit 534, switch lever 535, switch 536 and power leads 531.

An emergency lever 538 with switch 539 and leads 546 in parallel with brush 456 and circuit 536 is provided for operating the tilting magnets 369 in case of emergency, as when a mistake might be discovered during setting. This would be corrected by breaking line 563564 by switch 361, and then clearing the tilting magnets by switch 539, and rotating the clearing handle 345.

If it is desired to clear after setting and without printing, the clutch lever 466 may be drawn back and held manually while crank 463 is rotated. This is followed by turning clearing crank 345, when the machine will be in readiness for another setting.

It is to be noted in the diagrams that batteries are provided for each independent circuit. This may be obviated by sources of current in multiple if desired. Grounds are also shown for the sake of clearness, but in operations it is likely that complete metallic circuits would often be employed, all of which is within the scope and spirit of my invention.

The apparatus may be arranged for use with a separate circuit from each sending unit to each typewheel'unit, with an added circuit for the final impulse. This may be accomplished with high frequency multiple channel wired wireless methods well known in the art.

Fig. 25 is a diagram of the sending apparatus when each unit has a separate channel. Device 600 superimposes upon telephone line 60! with ground 602 and ear pieces 603, the multiple high frequency channels needed.

Transmitting units J, K, L, and M are provided, although a greater number may be used. To start the apparatus switch 62 is closed. This starts motor 35, fed from power leads I H. Motor 35 drives shaft 1, fitted with spur gears 6 and clutches 6,. After motor 35 starts shaft 1 it will rotate idly until magnets as J9, K9, L6 and M9 are caused to function. When they are en ergized and cause clutches to engage spur gears, discs J l, Kl, Li, and Ml cannotstart, being held by mechanical stop Me.

In order to energize the local clutch magnets, circuit 500 is formed. When the ticket inserted in the machine makes contact Hit-El l4 and switch 56 is closed, circuit 604 goes through par= allel leads to the clutch magnets, they being in parallel with its battery 605.

In the illustration, Fig. 25, the clutch magnet armatures K110 and Mill are shown closed, being in operation, while J 10 and L| are open, having already functioned.

The closingof armatures l0 creates the line circuits and closes the clutches. The commutator discs will now function when stop 64a is removed.

Owing to the settings of the keys and to the fact that all the discs start simultaneously, some will be stopped before others are stopped. When the prolonged impulses occur, magnets as 20 are caused to be energized, breaking their armature contacts. This de-energizes the clutch magnets and the clutches are disengaged, the discs returning to their initial positions independently of each 1 other.

As in this form of connections the last disc is not the one which can be depended on to send the last prolongation, means is provided to send a prolonged impulse upon the completion by the last disc of its prolonged impulse.

For this purpose magnet 606 is inserted in circuit 604. Whenall the contacts Jl23,'Ki20, MM and Mitt are broken, the whole circuit 504 goes dead, and magnet 606 is de-energized.

Magnet 606 has armature 608, on circuit 60l which includes contact 609, battery M6l0, contact at lever switch 63, and magnet 6i i. When magnet 606 is energized, armature 600 is attracted and contact 600 cannot be made. But when magnet 606 is de-energized by the braking of the clutch magnet circuits the circuit 601! is set up.

Magnet 5i i has armature 6|2 with ground 6l3. When M l is energized it makes contact 6 l 4, which sets up the final line circuit 6 l 5, battery 5 l5, magnet 6H and line lead 6I8, to device 600, arising at ground 6 l 3 and going to the printer. Contact 6 i4 is locked up as long as magnet Bil remains energized, but when the circuit goes dead from the printer, M4 is not broken because 6! l remains energized by circuit 601. It is nowdeenergized through switch 63 breaking circuit 60'5, which allows armature 6 E2 to retract and break 6114. Switch 6? is so arranged that circuit 604 is closed before 50'! is closed, so that armature 606 being attracted, circuit 60] cannot be set up at the outset. Or upon the mechanical restoration of contacts, as J i 23, through the clearing crank 32, magnet 606 is energized and circuit 601 prevented from being set up.

Thus the de-energization of magnet 606 through the breaking of all the local clutch contacts, sends a final direct current impulse to line which effects the function at the printer which was in the previous arrangement effected by the prolongation of the final disc impulse.

When switch 63 closes circuit 604 and engages all the clutches, and mechanical stops 64 and 64a are removed, the discs begin to send impulses to line. Disc J l starts circuit J2, by connection with batteries J I25, J l 26 and through brush 48 to lead J and thence to contact I24, magnet J i20 and to line at device 600.

The alternating impulses pass to line and the prolonged impulse energizes magnet J7'20, which attracts armature J:i22 and breaks contact J I23 which de-energizes magnet J 9. This causes contact 24 to be broken, and the clutch to be disengaged allowing disc Jl to return to its initial position. 1

Meanwhile all the other units have been functioning similarly, and when the last is finished, 6 i0 circuit is completed. After the printer breaks circuit BIB, switches 62 and 63 are turned off and the magnets and keys are cleared by the clearing cranks, ready for the next functioning.

When the high frequency multi-channel line reaches the printer, the channels are separated and deposed from the telephone line 100 at device ml, by means well known in the art.

Phone line E02 leads to ear phone 103 and ground 104. ur channel leads, equal in numher to the channels from the transmitting discs of the sender are provided, leading to magnets 634N, 3341?, 334Q and 334R.

' Circuit Nfl is made up of lead Na, magnet 334N- 334N, attracting 336N which is locked up by catch 344N. Current through Na, however, is not broken, as spring contact 34 IN does not separate from plate 508 of arm 506. The rising of arm 506, however, closes contact through spring 342N, block 509 and 343N. Arm 336N being locked up these contacts are held in force after which goes through lead M2 to magnet 43'IZ and back through lead M3 to common ground l0'l-'l00--l09.

The functioning of magnet 43lZ is similar to the function of magnet 43! previously described and the action of the printing crank and other parts is similar, and they are numbered similarly.

When two tickets are desired to be printed which are for adjoining seats and differ only by the seat numbers, or when tickets for seats in adjoining rows in a block are desired to be printed, I provide means for holding the main portion of the ticket printing wheels set, while only the' smaller portion including the numbers is changed. This saves the operators considerable time, as only a few wheels at the ends need to be re-set,

In the diagrams in which these portions are shown Figs. 23, 24, 25, 26, only four units are indicated, the retained set portion consisting of two units and the changeable portion of, two units, but any number of units may be included and the division made between them at any desired point.

Figs. 23 and 24 indicate the means used in connection with the single channel line, and Figs. 25, 26 the means used with the multiple channel line.

In Fig. 23 a switch, I43, is inserted in circuit AaI, in series. When this switch is closed, the circuit functions normally for the whole range of units. When the switch is opened circuit AaI. is dead. The switch goes over and creates circuit I44. Circuit I44 comprises contact I of switch I43, lead to switch 63, switch contact at switch 63, contacts II3-II4, battery I22 and leads to circuit CcI, circuit I44 being in parallel with the leads to contact BI9.

After transmitting an entire range of discs and after the printer is set to hold part of them and to re-set some, as 3IOG and 3IOH,- the sender operator clears his machine with the manual clearing levers and sets keys for discs GI and DI. The motor has been left running. He closes contact I45 with switch I43 and closes switch 63. Magnet A9 is thus by-passed and does not function, hence no signals can be sent by disc AI. As contact AI!) is not closed, depending on All! functioning, magnet B9 gets no current and disc BI cannot function. Circuit I44-CcI energizes magnet C9. The operator then frees discs C and D of stop 64a. Disc CI then sends current to line until the prolonged signal encrgizes magnet C020 and breaks the clutch magnet circuit, which in turn sets up the next circuit for disc DI. Any number of units may be bypassed at the outset and any desired number retained for the re-setting of the final typewheels of the printer.

In order to cause the printer to function in a corresponding manner, a by-pass unit-is inserted between magnets 334F and 334G, in the line at point 5I9. This by-pass unit could be inserted elsewhere, as desired, to agree with a different setting of switch I43 of the sender.

The by-pass consists of switch lever 361Z, magnet 313Z, switches and connections. The by-pass unit is switched in after the printer is set for a complete printing, but before the printing crank is turned. The following functions are brought into play to hold the typewheels desired to be held and to permit the clearing of the few to be re-set.

The operator cuts off the left hand units through breaking circuit 521 at switch 540.- He also cuts off the left hand part of circuit 532 with switch 54I. He also breaks line 5I9 with switches at three points, 542, 543, 544. The breaking of circuits 521 and 532 prevents any impulses from reaching the left hand units from the printing crank commutators, and so they remain set, without being cleared.

The operator now prints the ticket. In the function the units 3|0G and 3IOH clear. Switch starting lever 361 returns to contact 311, magnet 313 being energized by circuit 524. Annature 31I has an extra notch 546. Both notches are escaped by 361 when magnet 313 is energized.

In order to receive new impulses to set only units 3IOG and 3IOH, the operator turns the clearing crank 345, then throws lever 361 over to the point where it is caught by the second notch 546 of armature 311. This positions it in a median location, not making either contacts 316 or 311. No current can now pass to magnets 334E or 334F, and at the same time the line is not grounded. The operator then closes switch 545, setting up circuit EIZ, through lead magnet 334G, lead 5I3Z to armature 354G, thus supplying the second circuit to keep magnet 334G energized. When contact 351G is broken by the sender, magnet 334G is by-passed by lead 5I6Z, similar to lead 5I6, to spring contact 520, and so on to lead '52I to magnet 3341-1,

which then functions as when the whole range is operated. Units 3IOG and 3IIJH are now set. The second ticket is now set up. If the operator desires no more tickets adjoining he cuts circuit EIZ by turning off switch 545, and remakes contacts at 540, MI, 542, 543 and 544. He then turns the printing crank and the whole range of typewheels 'is cleared.

Magnet 313Z is in parallel with magnet 313, and when 361Z is freed and breaks contact 316Z, lever 361 is freed of the second notch 546 and 361 is returned to the initial position, while 361Z has cut out the by-pass unit, which can only be cut in again by the manual operation of Switch 548 is arranged to make and break contacts 540, Mi, 542,- 543 and 544 simultaneously.

In order to effect the same functioning in the high frequency channel wired apparatus, additions are made as indicated in Figs. 25 and 26.

In the sender Fig. 25, switch 62I is separately in series with I5I9 and 620, they being isolated from each other. As shown closed the switch permits normal operation of the whole range of sending discs. When it is opened it breaks contacts of magnets J9 and K9, which cannot then be energized by circuit 604. Units JI and KI are thus left idle and units LI and MI are free to function as before. 7 v

After settingthe first ticket and before setting for the coupon of the second ticket, the clearing cranks 32 and I02 are turned. Keys for discs LI and MI are then set and the apparatus started as before.

In Fig. 26 the printer is provided with a supplementary switch arm 361Y, similar to 361K, except that it makes contacts for each of the magnet circuits to be operated thereafter while 361X supplies current for all. The switch arm 351Z will serve the purpose when fitted with extra contacts.

When the entire printer is set for the first ticket the operator does not at once print. He first breaks contact 1I4,-cutting ofi circuit 521 from the units to the left, and he also cuts off the units to the left from circuit 532 by breaking contact 1I5. These circuits may be broken 'by switch 548 when it is not. connected with The printing of the first ticket now takes place. It frees units Q and R but cannot affect units N and Rwhich remain set. In order to re-set 3 IDQ and 3 I OR for the coupon of the second ticket, the clearing crank 345 is rotated; lever arm 361K is' closed to the second notch 546 and lever arm 361Y is set to the position shown in Fig. 26. The 

